KR20110049134A - Apparatus for fixing specimen for tensile test - Google Patents

Abstract

PURPOSE: A fixing device for a tensile bar is provided to reduce a measurement error range by preventing a fixed bar from moving in a longitudinal direction. CONSTITUTION: A fixing device for a tensile bar comprises a tensile testing machine. The tensile testing machine has an upper tension part(100a), a lower tension part(100b), and a fixed bar(102) fixed therein. A tensile specimen(20) is mounted in the tensile testing machine. A fixing hole is formed on one side of the tensile specimen. The fixed bar is press-fitted into the fixing hole. A female thread is formed on the inner side of the fixing hole. A male thread is formed on the outer surface of the fixed rod.

Description

Fixture for tensile test piece {APPARATUS FOR FIXING SPECIMEN FOR TENSILE TEST}

The present invention relates to a failure test device for a tensile test piece, more specifically, a tension capable of accurately measuring the data value according to the breaking resistance by fixing so as to evenly distribute the distribution load according to the curvature of the small tensile test piece bent at a constant curvature A fixture for a test piece.

For example, in a nuclear power plant or the like, it is necessary to accurately determine the failure characteristics of a piping system structure in order to apply the pre-break leakage design concept to the structure of the piping system that may be exposed to the risk of leakage of the handling material.

However, at present, the destruction characteristics are rarely obtained easily.

It is very difficult to carry out the actual test of the actual pipe because it takes a lot of cost and time to secure a large amount of pipe and to build a facility such as a test apparatus in order to obtain the fracture characteristic value for the piping system structure.

Therefore, the fracture characteristic value of the material is obtained through a test on a standard tensile test specimen, and the structural characteristics of the piping system structure are analyzed to evaluate the fracture characteristic. However, in the case of standard specimens, the curvature of the pipes is not taken into account in the geometric shape, and the fracture characteristics obtained through the test are different from the actual ones due to the constraint effect of the dimensions.

1 and 2 show a CT test piece 11 and a single edge notched bending (SENB) test piece 12 which are standard tensile test pieces presented by ASTM.

According to the standard tensile test specimen shown in Figs. 1 and 2, although there is an advantage that the tensile test piece shape and the tensile test method are standardized, not only a lot of constraints exist in the manufacture of the test piece due to the curvature and thickness of the pipe, but also the size and shape There is a problem that needs to be corrected for the effect of restraint effect caused by the change of.

In addition, Figure 3 and Figure 4 shows the seal pipe fracture tensile test piece, because the size and shape of the pipe is used the same as actually used, there is an advantage that does not need to compensate for the effect of restraint effect, but three-point bending It is difficult to consider the curvature of the pipe due to the machining of the jig 14 and 15 necessary for the test or the four-point bending test, and the length of the test piece 18 for performing the fracture toughness test is usually about 3 to 6 m. There is this.

Therefore, as the tensile test piece and the method described above, a curved CT test piece presented as a test piece that can evaluate the fracture resistance of the pipe material in consideration of the curvature of the pipe is used.

However, in the case of the standard tensile test piece, the straightness of the crack is secured because it is not bent in the thickness direction, and the load acts uniformly in the thickness direction of the tensile test piece, while in the case of the bent CT tensile test piece, the vertical direction is obtained by having the shape bent in the thickness direction. There is a problem in that additional moments vary depending on the position in the thickness direction other than the load, and since the degree of crack propagation on the left and right sides is changed by the generation of the moment, the reliability of the fracture characteristic value evaluated is lowered.

5 is a diagram showing the cutting tip 20 in the existing tensile test piece, and since the theoretical center virtual line A and the actual center virtual line B do not coincide with each other, the CT is bent at a constant curvature. Since the inner diameter of the tensile test piece is more advanced than the outer diameter, it is difficult to secure the straightness of the cracks at both ends of the crack.

As shown in FIG. 6, when the CT tensile test piece 20 is bent and used in a conventional jig, the tensile test piece 20 itself has a bent shape, and thus the cutting tip 25 of the cutout part 24 is used. Due to the problem that the center of the distribution load acting on the tensile test piece 20 is not located in the center, the measurement value cannot be measured accurately.

Accordingly, the present invention is to solve the problems of the prior art as described above, to fix the distributed load according to the curvature of the small tensile test piece bent at a certain curvature to accurately measure the data value according to the breaking resistance It is an object of the present invention to provide a fixing device for a tensile test piece.

In order to achieve the above object, the present invention, in the tensile tester having a tension test piece having an upper tension portion and a lower tension portion and a fixed rod fixed thereto, in a fixing device for a tensile test piece for mounting a tensile test piece, one side of the tensile test piece In the cutout portion and the fixing hole perforated in the thickness direction is formed, the fixing hole of the tensile test piece is configured to be clamped by the fixing rod position adjustment.

A female thread is formed at an inner side of the fixing hole, and a male thread is formed at a portion of the outer circumference of the fixing rod in the longitudinal direction.

In addition, pinholes are formed at both ends of the fixing rod, and the fixing pin is fitted into the pinhole to be fixed.

In addition, a male nut formed on the fixing rod is fitted with a fixing nut for fixing a tensile test piece.

According to the configuration of claim 1 of the present invention, it is possible to fix the distributed load according to the curvature of the small tensile test piece bent at a constant curvature evenly so that the data value according to the breaking resistance can be measured accurately and quickly. have.

According to the structure of Claim 2 of this invention, a female thread is formed in the inner side of a fixing hole, and a male thread is formed in the longitudinal direction in the outer peripheral part of the said fixed rod, and a tensile test piece is fixed, so that a tension test piece is not biased to either side. It is possible to apply evenly distributed load in the thickness direction, thereby reducing the measurement error significantly.

According to the structure of Claim 3 of this invention, since a pinhole is formed in a fixed rod, and a fixed pin is pinched in this pinhole, the fixed rod is prevented from moving in a longitudinal direction, and therefore there exists an effect which can reduce a measurement error range. .

According to the structure of Claim 4 of this invention, there exists an effect which can be reliably fixed so that a tension test piece may not be moved in the longitudinal direction of a fixed rod by inserting a fixed nut in the said fixed rod.

Hereinafter, with reference to the accompanying drawings, the configuration of the fixing device for tensile test piece of the present invention will be described in detail.

7 is a view showing a fixture for pipe tensile test pieces of the present invention, Figure 8 is a view showing a state of use of the fixture for tensile test piece of the present invention.

In the device for fixing a tensile test piece bent at a certain curvature of the present invention, the same components as in the prior art described in the detailed description will be given the same reference numerals, and the detailed description thereof will be omitted.

As shown in FIG. 7, the fixture for tensile test piece of the present invention forms a cutout portion 24 having a cutting tip 25 on one side of the tensile test piece 20 taken from a curved pipe for testing.

Fixing holes 22a and 22b are formed at both sides of the cutout 24 formed in the tensile test piece 20, respectively.

The tensile test piece 20 having a curved surface for mounting the tensile test piece 20 prepared in this way to a tension tester having an upper tension part 100a and a lower tension part 100b moved to both sides and a fixing rod 102 fixed thereto. The fixing rod 102 is forcibly fixed to the fixing holes 22a and 22b formed in

In fixing the fixing rod 102 to the fixing holes (22a, 22b) formed in the tensile test piece 20 as described above, to the upper tension portion (100a) and the lower tension portion (100b) of the tensile tester It can be tensioned by adjusting the clamped position to apply an even distribution load in the thickness direction of the tension piece 20.

Therefore, as described above, the fixing rod 102 can be quickly inserted into the fixing holes 22a and 22b of the tensile test piece 20 by fastening and can significantly reduce the time required for the measurement work.

In the present invention, as shown in FIG. 7, a female thread is formed in the inner side of the fixing holes 22a and 22b of the tensile test piece 20 so that the tensile test can be performed in a state where the fixing force is further increased. It is.

After forming the female screw thread 23 in the fixing holes 22a, 22b as described above, and forming the male screw thread 101 in the longitudinal direction in the fixing rod 102 so that the female screw thread 23 can be fixed and engaged therewith, the male screw thread ( 101 is screwed to the female thread 23 of the tensile test piece 20, and the tensile test piece 20 is moved along the male thread 101 of the fixing rod 102 while tightening by tightening the female thread 23 of the tensile test piece 20. It can be easily fixed on the position of (A).

In this way, the tensile test piece 20 can be fixed by the fixing rod 102 and at the same time can be adjusted to the position of the theoretical center virtual line A, thereby reducing the time for fixing and measuring work. In particular, in the present invention, since the male thread (101) is formed on the fixing rod (102), the female thread (23) of the tensile test piece (20) fixed through this can be moved to perform a fine fixing operation.

In addition, in the present invention, pin holes 103 are formed at both ends of the fixed rod 102, and the pin rod 103 is inserted into the upper tension portion 100a and the lower tension portion 100b. Since the fixing pin 105 is inserted into the fixing pin 105, the length of the upper pin 100a and the lower pin 100b does not fall out in the longitudinal direction, and the length is fixed by the fixing pin 105. By maintaining the fixed state, the distribution load of the tensile force generated during the tensile test can be uniformly applied.

In particular, the tension piece 20 inserted in the male thread 101 formed along the longitudinal direction of a part of the fixing rod 102 is not easily moved in the longitudinal direction of the fixing rod 102, in order to increase the fixing force. A fixing nut 109 is further inserted and fixed so that the tensile test piece 20 which is fitted and fixed in the longitudinal direction of the fixing rod 102 does not push to either side.

The fixing nut 109 inserted and fixed to the fixing rod 102 is fixed while being rotated by the male thread 101 formed on the fixing rod 102 so that the fixing nut 109 is fixed in the longitudinal direction of the fixing rod 102. Has a holding force such that the test tension punch 20 cannot move.

In the present invention configured as described above, the female thread 23 formed on the male thread 101 and the tensile test piece 20 of the fixing rod 102 and the fixing nut 109 additionally inserted into and fixed to the fixing rod 102. As shown in FIG. 8, the tensioning operation can be performed by adjusting the center line so that an evenly distributed load is applied to the center of the thickness of the tensile test piece 20.

1 is a view showing a conventional standard tension piece.

2 shows a conventional standard SENB tension piece.

3 is a view showing a conventional seal pipe fracture toughness tension piece.

Figure 4 is a view showing a tension piece of another conventional pipe failure toughness test.

5 shows a theoretical center virtual line and a real center virtual line of a conventional tension piece.

7 is a view showing a fixing device for a tensile test piece of the present invention.

Figure 8 is a view showing a state of use of the fixing device for tensile test piece of the present invention.

A brief description of the symbols for the main parts of the drawing

20: tension piece

24: cutout

22a, 22b: fixing hole

23: female thread

25: push pin

103: pinhole

100a: upper tension part

100b: lower tension part

101: male thread

102: fixed rod

109: retaining nut

Claims (4)

In a tension tester having an upper tension portion (100a) and a lower tension portion (100b) and a fixed rod 102 fixed thereto, in the fixing device for a tensile test piece for mounting a tensile test piece 20, One side of the tensile test piece 20 is formed with a cutout 24 and fixing holes 22a and 22b bored in the thickness direction, Fixing device for the tensile test piece, characterized in that the fixing bar (102a), (22b) of the tensile test piece (20) is fixed to the fixing rod 102 is positioned. The method of claim 1, wherein the female thread 23 is formed in the inner portion of the fixing holes (22a), 22b, the male thread 101 is formed in the longitudinal direction of a portion of the outer circumference of the fixing rod 102 A fixture for tensile test pieces, characterized in that According to claim 1 or claim 2, wherein the pin rod 103 is formed on both ends of the fixing rod 102, the fixing pin for the tensile test piece characterized in that the fixing pin 105 is fitted into the pin hole 103 is fixed. . 4. The holding device for tensile test piece according to claim 3, wherein a fixing nut (109) for fixing the tensile test piece (20) is fitted to the male thread (101) formed in the fixing rod (102).

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